1 416 94 ANALYSIS OF THE DYNAMIC ABERRANT LANDSCAPE OF DNA METHYLATION AND GENE EXPRESSION DURING ARSENIC-INDUCED CELL TRANSFORMATION. INORGANIC ARSENIC IS A WELL-KNOWN CARCINOGEN ASSOCIATED WITH SEVERAL TYPES OF CANCER, BUT THE MECHANISMS INVOLVED IN ARSENIC-INDUCED CARCINOGENESIS ARE NOT FULLY UNDERSTOOD. RECENT EVIDENCE POINTS TO EPIGENETIC DYSREGULATION AS AN IMPORTANT MECHANISM IN THIS PROCESS; HOWEVER, THE EFFECTS OF EPIGENETIC ALTERATIONS IN GENE EXPRESSION HAVE NOT BEEN EXPLORED IN DEPTH. USING MICROARRAY DATA AND APPLYING A MULTIVARIATE CLUSTERING ANALYSIS IN A GAUSSIAN MIXTURE MODEL, WE DESCRIBE THE ALTERATIONS IN DNA METHYLATION AROUND THE PROMOTER REGION AND THE IMPACT ON GENE EXPRESSION IN HACAT CELLS DURING THE TRANSFORMATION PROCESS CAUSED BY CHRONIC EXPOSURE TO ARSENIC. USING THIS CLUSTERING APPROACH, THE GENES WERE GROUPED ACCORDING TO THEIR METHYLATION AND EXPRESSION STATUS IN THE EPIGENETIC LANDSCAPE, AND THE CHANGES THAT OCCURRED DURING THE CELLULAR TRANSFORMATION WERE IDENTIFIED ADEQUATELY. THUS, WE PRESENT A VALUABLE METHOD FOR IDENTIFYING EPIGENOMIC DYSREGULATION. 2019 2 6562 42 TRANSIENT AND PERMANENT CHANGES IN DNA METHYLATION PATTERNS IN INORGANIC ARSENIC-MEDIATED EPITHELIAL-TO-MESENCHYMAL TRANSITION. CHRONIC LOW DOSE INORGANIC ARSENIC EXPOSURE CAUSES CELLS TO TAKE ON AN EPITHELIAL-TO-MESENCHYMAL PHENOTYPE, WHICH IS A CRUCIAL PROCESS IN CARCINOGENESIS. INORGANIC ARSENIC IS NOT A MUTAGEN AND THUS EPIGENETIC ALTERATIONS HAVE BEEN IMPLICATED IN THIS PROCESS. INDEED, DURING THE EPITHELIAL-TO-MESENCHYMAL TRANSITION, MORPHOLOGIC CHANGES TO CELLS CORRELATE WITH CHANGES IN CHROMATIN STRUCTURE AND GENE EXPRESSION, ULTIMATELY DRIVING THIS PROCESS. HOWEVER, STUDIES ON THE EFFECTS OF INORGANIC ARSENIC EXPOSURE/WITHDRAWAL ON THE EPITHELIAL-TO-MESENCHYMAL TRANSITION AND THE IMPACT OF EPIGENETIC ALTERATIONS IN THIS PROCESS ARE LIMITED. IN THIS STUDY WE USED HIGH-RESOLUTION MICROARRAY ANALYSIS TO MEASURE THE CHANGES IN DNA METHYLATION IN CELLS UNDERGOING INORGANIC ARSENIC-INDUCED EPITHELIAL-TO-MESENCHYMAL TRANSITION, AND ON THE REVERSAL OF THIS PROCESS, AFTER REMOVAL OF THE INORGANIC ARSENIC EXPOSURE. WE FOUND THAT CELLS EXPOSED TO CHRONIC, LOW-DOSE INORGANIC ARSENIC EXPOSURE SHOWED 30,530 SITES WERE DIFFERENTIALLY METHYLATED, AND WITH INORGANIC ARSENIC WITHDRAWAL SEVERAL DIFFERENTIAL METHYLATED SITES WERE REVERSED, ALBEIT NOT COMPLETELY. FURTHERMORE, THESE CHANGES IN DNA METHYLATION MAINLY CORRELATED WITH CHANGES IN GENE EXPRESSION AT MOST SITES TESTED BUT NOT AT ALL. THIS STUDY SUGGESTS THAT DNA METHYLATION CHANGES ON GENE EXPRESSION ARE NOT CLEAR-CUT AND PROVIDE A PLATFORM TO BEGIN TO UNCOVER THE RELATIONSHIP BETWEEN DNA METHYLATION AND GENE EXPRESSION, SPECIFICALLY WITHIN THE CONTEXT OF INORGANIC ARSENIC TREATMENT. 2017 3 2483 27 EPIGENETIC VARIATION AND HUMAN DISEASE. CYTOSINE GUANINE DINUCLEOTIDE (CPG) ISLAND METHYLATION IS A KNOWN MECHANISM OF EPIGENETIC INHERITANCE IN POSTMEIOTIC CELLS. THROUGH ASSOCIATED CHROMATIN CHANGES AND SILENCING, SUCH EPIGENETIC STATES CAN INFLUENCE CELLULAR PHYSIOLOGY AND AFFECT DISEASE RISK AND SEVERITY. OUR STUDIES OF CPG ISLAND METHYLATION IN NORMAL COLORECTAL MUCOSA REVEALED PROGRESSIVE AGE-RELATED INCREASES AT MULTIPLE GENE LOCI, SUGGESTING GENOME-WIDE MOLECULAR ALTERATIONS WITH POTENTIAL TO SILENCE GENE EXPRESSION. HOWEVER, THERE WAS CONSIDERABLE VARIATION IN THE DEGREE OF METHYLATION AMONG INDIVIDUALS OF COMPARABLE AGES. SUCH VARIATION COULD BE RELATED TO GENETIC FACTORS, LIFESTYLE, OR ENVIRONMENTAL EXPOSURES. STUDIES IN ULCERATIVE COLITIS AND HEPATOCELLULAR CIRRHOSIS AND NEOPLASIA REVEALED THAT CHRONIC INFLAMMATORY STATES ARE ACCOMPANIED BY MARKED INCREASES IN CPG ISLAND METHYLATION IN NORMAL-APPEARING TISSUES, CONFIRMING THE HYPOTHESIS THAT PROINFLAMMATORY EXPOSURES COULD ACCOUNT FOR PART OF THE EPIGENETIC VARIATION IN HUMAN POPULATIONS. PRELIMINARY DATA ALSO SUGGEST POTENTIAL INFLUENCES OF LIFESTYLE AND EXPOSURE FACTORS ON CPG ISLAND METHYLATION. IT IS SUGGESTED THAT EPIGENETIC VARIATION RELATED TO AGING, LIFESTYLE, EXPOSURES AND POSSIBLY GENETIC FACTORS, IS ONE OF THE MODULATORS OF ACQUIRED, AGE-RELATED HUMAN DISEASES, INCLUDING NEOPLASIA. 2002 4 1655 26 DOSE-DEPENDENCE, SEX- AND TISSUE-SPECIFICITY, AND PERSISTENCE OF RADIATION-INDUCED GENOMIC DNA METHYLATION CHANGES. RADIATION IS A WELL-KNOWN GENOTOXIC AGENT AND HUMAN CARCINOGEN THAT GIVES RISE TO A VARIETY OF LONG-TERM EFFECTS. ITS DETRIMENTAL INFLUENCE ON CELLULAR FUNCTION IS ACTIVELY STUDIED NOWADAYS. ONE OF THE MOST ANALYZED, YET LEAST UNDERSTOOD LONG-TERM EFFECTS OF IONIZING RADIATION IS TRANSGENERATIONAL GENOMIC INSTABILITY. THE INHERITANCE OF GENOMIC INSTABILITY SUGGESTS THE POSSIBLE INVOLVEMENT OF EPIGENETIC MECHANISMS, SUCH AS CHANGES OF THE METHYLATION OF CYTOSINE RESIDUES LOCATED WITHIN CPG DINUCLEOTIDES. IN THE CURRENT STUDY WE EVALUATED THE DOSE-DEPENDENCE OF THE RADIATION-INDUCED GLOBAL GENOME DNA METHYLATION CHANGES. WE ALSO ANALYZED THE EFFECTS OF ACUTE AND CHRONIC HIGH DOSE (5GY) EXPOSURE ON DNA METHYLATION IN LIVER, SPLEEN, AND LUNG TISSUES OF MALE AND FEMALE MICE AND EVALUATED THE POSSIBLE PERSISTENCE OF THE RADIATION-INDUCED DNA METHYLATION CHANGES. HERE WE REPORT THAT RADIATION-INDUCED DNA METHYLATION CHANGES WERE SEX- AND TISSUE-SPECIFIC, DOSE-DEPENDENT, AND PERSISTENT. IN PARALLEL WE HAVE STUDIED THE LEVELS OF DNA DAMAGE IN THE EXPOSED TISSUES. BASED ON THE CORRELATION BETWEEN THE LEVELS OF DNA METHYLATION AND DNA DAMAGE WE PROPOSE THAT RADIATION-INDUCED GLOBAL GENOME DNA HYPOMETHYLATION IS DNA REPAIR-RELATED. 2004 5 1508 39 DNA METHYLATION AND MRNA AND MICRORNA EXPRESSION OF SLE CD4+ T CELLS CORRELATE WITH DISEASE PHENOTYPE. SYSTEMIC LUPUS ERYTHEMATOSUS (SLE) IS AN AUTOIMMUNE DISEASE WELL KNOWN FOR ITS CLINICAL HETEROGENEITY, AND ITS ETIOLOGY SECONDARY TO A CROSS-TALK INVOLVING GENETIC PREDISPOSITION AND ENVIRONMENTAL STIMULI. ALTHOUGH GENOME-WIDE ANALYSIS HAS CONTRIBUTED GREATLY TO OUR UNDERSTANDING OF THE GENETIC BASIS OF SLE, THERE IS INCREASING EVIDENCE FOR A ROLE OF EPIGENETICS. INDEED, RECENT DATA HAVE DEMONSTRATED THAT IN PATIENTS WITH SLE, THERE ARE STRIKING ALTERATIONS OF DNA METHYLATION, HISTONE MODIFICATIONS, AND DEREGULATED MICRORNA EXPRESSION, THE SUM OF WHICH CONTRIBUTE TO OVER-EXPRESSION OF SELECT AUTOIMMUNE-RELATED GENES AND LOSS OF TOLERANCE. TO ADDRESS THIS ISSUE AT THE LEVEL OF CLINICAL PHENOTYPE, WE PERFORMED DNA METHYLATION, MRNA AND MICRORNA EXPRESSION SCREENING USING HIGH-THROUGHPUT SEQUENCING OF PURIFIED CD4+ T CELLS FROM PATIENTS WITH SLE, COMPARED TO AGE AND SEX MATCHED CONTROLS. IN PARTICULAR, WE STUDIED 42 PATIENTS WITH SLE AND DIVIDED THIS GROUP INTO THREE CLINICAL PHENOTYPES: A) THE PRESENCE OF SKIN LESIONS WITHOUT SIGNS OF SYSTEMIC PATHOLOGY; B) SKIN LESIONS BUT ALSO CHRONIC RENAL PATHOLOGY; AND C) SKIN LESIONS, CHRONIC RENAL PATHOLOGY AND POLYARTICULAR DISEASE. INTERESTINGLY, AND AS EXPECTED, SEQUENCING DATA REVEALED CHANGES IN DNA METHYLATION IN SLE COMPARED TO CONTROLS. HOWEVER, AND MORE IMPORTANTLY, ALTHOUGH THERE WERE COMMON METHYLATION CHANGES FOUND IN ALL GROUPS OF SLE COMPARED TO CONTROLS, THERE WAS SPECIFIC DNA METHYLATION CHANGES THAT CORRELATED WITH CLINICAL PHENOTYPE. THESE INCLUDED CHANGES IN THE NOVEL KEY TARGET GENES NLRP2, CD300LB AND S1PR3, AS WELL AS CHANGES IN THE CRITICAL PATHWAYS, INCLUDING THE ADHERENS JUNCTION AND LEUKOCYTE TRANSENDOTHELIAL MIGRATION. WE ALSO NOTED THAT A SIGNIFICANT PROPORTION OF GENES UNDERGOING DNA METHYLATION CHANGES WERE INVERSELY CORRELATED WITH GENE EXPRESSION AND THAT MIRNA SCREENING REVEALED THE EXISTENCE OF SUBSETS WITH CHANGES IN EXPRESSION. INTEGRATED ANALYSIS OF THIS DATA HIGHLIGHTS SPECIFIC SETS OF MIRNAS CONTROLLED BY DNA METHYLATION, AND GENES THAT ARE ALTERED BY METHYLATION AND TARGETED BY MIRNAS. IN CONCLUSION, OUR FINDINGS SUGGEST SELECT EPIGENETIC MECHANISMS THAT CONTRIBUTE TO CLINICAL PHENOTYPES AND FURTHER SHED LIGHT ON A NEW VENUE FOR BASIC SLE RESEARCH. 2014 6 4228 23 METHYLATION OF INFLAMMATORY CELLS IN LUNG DISEASES. THIS CHAPTER OVERVIEWS ROLES OF DNA METHYLATION IN INFLAMMATORY CELL BIOLOGY WITH THE FOCUSES ON LYMPHOCYTES AND MACROPHAGES/MONOCYTES IN LUNG DISEASES, ALTHOUGH THE MOLECULAR MECHANISMS BY WHICH TARGET GENES ARE METHYLATED AND REGULATED IN LUNG DISEASES REMAIN UNCLEAR. MOST OF EPIGENETIC STUDIES ON DNA METHYLATION OF TARGET GENES IN LUNG DISEASES MAINLY DEMONSTRATED THE CORRELATION OF DNA METHYLATION OF TARGET GENES WITH THE LEVELS OF OTHER CORRESPONDING FACTORS, WITH THE SPECIFICITY OF CLINICAL PHENOMES, AND WITH THE SEVERITY OF LUNG DISEASES. THERE IS AN URGENT NEED TO IDENTIFY AND VALIDATE THE SPECIFICITY AND REGULATORY MECHANISMS OF INFLAMMATORY CELL EPIGENETICS IN DEPTH. THE EPIGENETIC HETEROGENEITY AMONG DIFFERENT SUBSETS OF T CELLS AND AMONG PROMOTERS OR NON-PROMOTERS OF TARGET GENES SHOULD BE FURTHERMORE CLARIFIED IN ACUTE OR CHRONIC LUNG DISEASES AND CANCERS. THE HYPER/HYPO-METHYLATION AND MODIFICATIONS OF CHROMOSOL AND EXTRACHROMOSOMAL DNA MAY RESULT IN ALTERNATIONS IN PROTEINS WITHIN INFLAMMATORY CELLS, WHICH CAN BE IDENTIFIED AS DISEASE-SPECIFIC BIOMARKERS AND THERAPEUTIC TARGETS. 2020 7 3738 36 INORGANIC ARSENIC-INDUCED CELLULAR TRANSFORMATION IS COUPLED WITH GENOME WIDE CHANGES IN CHROMATIN STRUCTURE, TRANSCRIPTOME AND SPLICING PATTERNS. BACKGROUND: ARSENIC (AS) EXPOSURE IS A SIGNIFICANT WORLDWIDE ENVIRONMENTAL HEALTH CONCERN. LOW DOSE, CHRONIC ARSENIC EXPOSURE HAS BEEN ASSOCIATED WITH A HIGHER THAN NORMAL RISK OF SKIN, LUNG, AND BLADDER CANCER, AS WELL AS CARDIOVASCULAR DISEASE AND DIABETES. WHILE ARSENIC-INDUCED BIOLOGICAL CHANGES PLAY A ROLE IN DISEASE PATHOLOGY, LITTLE IS KNOWN ABOUT THE DYNAMIC CELLULAR CHANGES RESULTING FROM ARSENIC EXPOSURE AND WITHDRAWAL. RESULTS: IN THESE STUDIES, WE SOUGHT TO UNDERSTAND THE MOLECULAR MECHANISMS BEHIND THE BIOLOGICAL CHANGES INDUCED BY ARSENIC EXPOSURE. A COMPREHENSIVE GLOBAL APPROACH WAS EMPLOYED TO DETERMINE GENOME-WIDE CHANGES TO CHROMATIN STRUCTURE, TRANSCRIPTOME PATTERNS AND SPLICING PATTERNS IN RESPONSE TO CHRONIC LOW DOSE ARSENIC AND ITS SUBSEQUENT WITHDRAWAL. OUR RESULTS SHOW THAT CELLS EXPOSED TO CHRONIC LOW DOSES OF SODIUM ARSENITE HAVE DISTINCT TEMPORAL AND COORDINATED CHROMATIN, GENE EXPRESSION, AND MIRNA CHANGES CONSISTENT WITH DIFFERENTIATION AND ACTIVATION OF MULTIPLE BIOCHEMICAL PATHWAYS. MOST OF THESE TEMPORAL PATTERNS IN GENE EXPRESSION ARE REVERSED WHEN ARSENIC IS WITHDRAWN. HOWEVER, SOME GENE EXPRESSION PATTERNS REMAINED ALTERED, PLAUSIBLY AS A RESULT OF AN ADAPTIVE RESPONSE BY CELLS. ADDITIONALLY, THE CORRELATION OF CHANGES TO GENE EXPRESSION AND CHROMATIN STRUCTURE SOLIDIFY THE ROLE OF CHROMATIN STRUCTURE IN GENE REGULATORY CHANGES DUE TO ARSENITE EXPOSURE. LASTLY, WE SHOW THAT ARSENITE EXPOSURE INFLUENCES GENE REGULATION BOTH AT THE INITIATION OF TRANSCRIPTION AS WELL AS AT THE LEVEL OF SPLICING. CONCLUSIONS: OUR RESULTS SHOW THAT ADAPTATION OF CELLS TO IAS-MEDIATED EMT IS COUPLED TO CHANGES IN CHROMATIN STRUCTURE EFFECTING DIFFERENTIAL TRANSCRIPTIONAL AND SPLICING PATTERNS OF GENES. THESE STUDIES PROVIDE NEW INSIGHTS INTO THE MECHANISM OF IAS-MEDIATED PATHOLOGY, WHICH INCLUDES EPIGENETIC CHROMATIN CHANGES COUPLED WITH CHANGES TO THE TRANSCRIPTOME AND SPLICING PATTERNS OF KEY GENES. 2015 8 2033 31 EPIGENETIC CHANGES IN SOLID AND HEMATOPOIETIC TUMORS. THERE ARE THREE CONNECTED MOLECULAR MECHANISMS OF EPIGENETIC CELLULAR MEMORY IN MAMMALIAN CELLS: DNA METHYLATION, HISTONE MODIFICATIONS, AND RNA INTERFERENCE. THE FIRST TWO HAVE NOW BEEN FIRMLY LINKED TO NEOPLASTIC TRANSFORMATION. HYPERMETHYLATION OF CPG-RICH PROMOTERS TRIGGERS LOCAL HISTONE CODE MODIFICATIONS RESULTING IN A CELLULAR CAMOUFLAGE MECHANISM THAT SEQUESTERS GENE PROMOTERS AWAY FROM TRANSCRIPTION FACTORS AND RESULTS IN STABLE SILENCING. THIS NORMALLY RESTRICTED MECHANISM IS UBIQUITOUSLY USED IN CANCER TO SILENCE HUNDREDS OF GENES, AMONG WHICH SOME CRITICALLY CONTRIBUTE TO THE NEOPLASTIC PHENOTYPE. VIRTUALLY EVERY PATHWAY IMPORTANT TO CANCER FORMATION IS AFFECTED BY THIS PROCESS. METHYLATION PROFILING OF HUMAN CANCERS REVEALS TISSUE-SPECIFIC EPIGENETIC SIGNATURES, AS WELL AS TUMOR-SPECIFIC SIGNATURES, REFLECTING IN PARTICULAR THE PRESENCE OF EPIGENETIC INSTABILITY IN A SUBSET OF CANCERS AFFECTED BY THE CPG ISLAND METHYLATOR PHENOTYPE. GENERALLY, METHYLATION PATTERNS CAN BE TRACED TO A TISSUE-SPECIFIC, PROLIFERATION-DEPENDENT ACCUMULATION OF ABERRANT PROMOTER METHYLATION IN AGING TISSUES, A PROCESS THAT CAN BE ACCELERATED BY CHRONIC INFLAMMATION AND LESS WELL-DEFINED MECHANISMS INCLUDING, POSSIBLY, DIET AND GENETIC PREDISPOSITION. THE EPIGENETIC MACHINERY CAN ALSO BE ALTERED IN CANCER BY SPECIFIC LESIONS IN EPIGENETIC EFFECTOR GENES, OR BY ABERRANT RECRUITMENT OF THESE GENES BY MUTANT TRANSCRIPTION FACTORS AND COACTIVATORS. EPIGENETIC PATTERNS ARE PROVING CLINICALLY USEFUL IN HUMAN ONCOLOGY VIA RISK ASSESSMENT, EARLY DETECTION, AND PROGNOSTIC CLASSIFICATION. PHARMACOLOGIC MANIPULATION OF THESE PATTERNS-EPIGENETIC THERAPY-IS ALSO POISED TO CHANGE THE WAY WE TREAT CANCER IN THE CLINIC. 2005 9 3072 43 GENOME-WIDE DNA METHYLATION REPROGRAMMING IN RESPONSE TO INORGANIC ARSENIC LINKS INHIBITION OF CTCF BINDING, DNMT EXPRESSION AND CELLULAR TRANSFORMATION. CHRONIC LOW DOSE INORGANIC ARSENIC (IAS) EXPOSURE LEADS TO CHANGES IN GENE EXPRESSION AND EPITHELIAL-TO-MESENCHYMAL TRANSFORMATION. DURING THIS TRANSFORMATION, CELLS ADOPT A FIBROBLAST-LIKE PHENOTYPE ACCOMPANIED BY PROFOUND GENE EXPRESSION CHANGES. WHILE MANY MECHANISMS HAVE BEEN IMPLICATED IN THIS TRANSFORMATION, STUDIES THAT FOCUS ON THE ROLE OF EPIGENETIC ALTERATIONS IN THIS PROCESS ARE JUST EMERGING. DNA METHYLATION CONTROLS GENE EXPRESSION IN PHYSIOLOGIC AND PATHOLOGIC STATES. SEVERAL STUDIES SHOW ALTERATIONS IN DNA METHYLATION PATTERNS IN IAS-MEDIATED PATHOGENESIS, BUT THESE STUDIES FOCUSED ON SINGLE GENES. WE PRESENT A COMPREHENSIVE GENOME-WIDE DNA METHYLATION ANALYSIS USING METHYL-SEQUENCING TO MEASURE CHANGES BETWEEN NORMAL AND IAS-TRANSFORMED CELLS. ADDITIONALLY, THESE DIFFERENTIAL METHYLATION CHANGES CORRELATED POSITIVELY WITH CHANGES IN GENE EXPRESSION AND ALTERNATIVE SPLICING. INTERESTINGLY, MOST OF THESE DIFFERENTIALLY METHYLATED GENES FUNCTION IN CELL ADHESION AND COMMUNICATION PATHWAYS. TO GAIN INSIGHT INTO HOW GENOMIC DNA METHYLATION PATTERNS ARE REGULATED DURING IAS-MEDIATED CARCINOGENESIS, WE SHOW THAT IAS PROBABLY TARGETS CTCF BINDING AT THE PROMOTER OF DNA METHYLTRANSFERASES, REGULATING THEIR EXPRESSION. THESE FINDINGS REVEAL HOW CTCF BINDING REGULATES DNA METHYLTRANSFERASE TO REPROGRAM THE METHYLOME IN RESPONSE TO AN ENVIRONMENTAL TOXIN. 2017 10 5067 31 PHYSICAL ACTIVITY AND DNA METHYLATION IN HUMANS. PHYSICAL ACTIVITY IS A STRONG STIMULUS INFLUENCING THE OVERALL PHYSIOLOGY OF THE HUMAN BODY. EXERCISES LEAD TO BIOCHEMICAL CHANGES IN VARIOUS TISSUES AND EXERT AN IMPACT ON GENE EXPRESSION. EXERCISE-INDUCED CHANGES IN GENE EXPRESSION MAY BE MEDIATED BY EPIGENETIC MODIFICATIONS, WHICH REARRANGE THE CHROMATIN STRUCTURE AND THEREFORE MODULATE ITS ACCESSIBILITY FOR TRANSCRIPTION FACTORS. ONE OF SUCH EPIGENETIC MARK IS DNA METHYLATION THAT INVOLVES AN ATTACHMENT OF A METHYL GROUP TO THE FIFTH CARBON OF CYTOSINE RESIDUE PRESENT IN CG DINUCLEOTIDES (CPG). DNA METHYLATION IS CATALYZED BY A FAMILY OF DNA METHYLTRANSFERASES. THIS REVERSIBLE DNA MODIFICATION RESULTS IN THE RECRUITMENT OF PROTEINS CONTAINING METHYL BINDING DOMAIN AND FURTHER TRANSCRIPTIONAL CO-REPRESSORS LEADING TO THE SILENCING OF GENE EXPRESSION. THE ACCUMULATION OF CPG DINUCLEOTIDES, REFERRED AS CPG ISLANDS, OCCURS AT THE PROMOTER REGIONS IN A GREAT MAJORITY OF HUMAN GENES. THEREFORE, CHANGES IN DNA METHYLATION PROFILE AFFECT THE TRANSCRIPTION OF MULTIPLE GENES. A GROWING BODY OF EVIDENCE INDICATES THAT EXERCISE TRAINING MODULATES DNA METHYLATION IN MUSCLES AND ADIPOSE TISSUE. SOME OF THESE EPIGENETIC MARKERS WERE ASSOCIATED WITH A REDUCED RISK OF CHRONIC DISEASES. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE ABOUT THE INFLUENCE OF PHYSICAL ACTIVITY ON THE DNA METHYLATION STATUS IN HUMANS. 2021 11 3824 32 INVESTIGATING THE EPIGENETIC EFFECTS OF A PROTOTYPE SMOKE-DERIVED CARCINOGEN IN HUMAN CELLS. GLOBAL LOSS OF DNA METHYLATION AND LOCUS/GENE-SPECIFIC GAIN OF DNA METHYLATION ARE TWO DISTINCT HALLMARKS OF CARCINOGENESIS. ABERRANT DNA METHYLATION IS IMPLICATED IN SMOKING-RELATED LUNG CANCER. IN THIS STUDY, WE HAVE COMPREHENSIVELY INVESTIGATED THE MODULATION OF DNA METHYLATION CONSEQUENT TO CHRONIC EXPOSURE TO A PROTOTYPE SMOKE-DERIVED CARCINOGEN, BENZO[A]PYRENE DIOL EPOXIDE (B[A]PDE), IN GENOMIC REGIONS OF SIGNIFICANCE IN LUNG CANCER, IN NORMAL HUMAN CELLS. WE HAVE USED A PULLDOWN ASSAY FOR ENRICHMENT OF THE CPG METHYLATED FRACTION OF CELLULAR DNA COMBINED WITH MICROARRAY PLATFORMS, FOLLOWED BY EXTENSIVE VALIDATION THROUGH CONVENTIONAL BISULFITE-BASED ANALYSIS. HERE, WE DEMONSTRATE STRIKINGLY SIMILAR PATTERNS OF DNA METHYLATION IN NON-TRANSFORMED B[A]PDE-TREATED CELLS VS CONTROL USING HIGH-THROUGHPUT MICROARRAY-BASED DNA METHYLATION PROFILING CONFIRMED BY CONVENTIONAL BISULFITE-BASED DNA METHYLATION ANALYSIS. THE ABSENCE OF ABERRANT DNA METHYLATION IN OUR MODEL SYSTEM WITHIN A TIMEFRAME THAT PRECEDES CELLULAR TRANSFORMATION SUGGESTS THAT FOLLOWING CARCINOGEN EXPOSURE, OTHER AS YET UNKNOWN FACTORS (SECONDARY TO CARCINOGEN TREATMENT) MAY HELP INITIATE GLOBAL LOSS OF DNA METHYLATION AND REGION-SPECIFIC GAIN OF DNA METHYLATION, WHICH CAN, IN TURN, CONTRIBUTE TO LUNG CANCER DEVELOPMENT. UNVEILING THE INITIATING EVENTS THAT CAUSE ABERRANT DNA METHYLATION IN LUNG CANCER HAS TREMENDOUS PUBLIC HEALTH RELEVANCE, AS IT CAN HELP DEFINE FUTURE STRATEGIES FOR EARLY DETECTION AND PREVENTION OF THIS HIGHLY LETHAL DISEASE. 2010 12 2122 35 EPIGENETIC IMPACT OF INFECTION ON CARCINOGENESIS: MECHANISMS AND APPLICATIONS. VIRAL AND BACTERIAL INFECTIONS ARE INVOLVED IN THE DEVELOPMENT OF HUMAN CANCERS, SUCH AS LIVER, NASOPHARYNGEAL, CERVICAL, HEAD AND NECK, AND GASTRIC CANCERS. ABERRANT DNA METHYLATION IS FREQUENTLY PRESENT IN THESE CANCERS, AND SOME OF THE ABERRANTLY METHYLATED GENES ARE CAUSALLY INVOLVED IN CANCER DEVELOPMENT AND PROGRESSION. NOTABLY, ABERRANT DNA METHYLATION CAN BE PRESENT EVEN IN NON-CANCEROUS OR PRECANCEROUS TISSUES, AND ITS LEVELS CORRELATE WITH THE RISK OF CANCER DEVELOPMENT, PRODUCING A SO-CALLED 'EPIGENETIC FIELD FOR CANCERIZATION'. MECHANISTICALLY, MOST VIRAL OR BACTERIAL INFECTIONS INDUCE DNA METHYLATION INDIRECTLY VIA CHRONIC INFLAMMATION, BUT RECENT STUDIES HAVE INDICATED THAT SOME VIRUSES HAVE DIRECT EFFECTS ON THE EPIGENETIC MACHINERY OF HOST CELLS. FROM A TRANSLATIONAL VIEWPOINT, A RECENT MULTICENTER PROSPECTIVE COHORT STUDY DEMONSTRATED THAT ASSESSMENT OF THE EXTENT OF ALTERATIONS IN DNA METHYLATION IN NON-CANCEROUS TISSUES CAN BE USED TO PREDICT CANCER RISK. FURTHERMORE, SUPPRESSION OF ABERRANT DNA METHYLATION WAS SHOWN TO BE A USEFUL STRATEGY FOR CANCER PREVENTION IN AN ANIMAL MODEL. HERE, WE REVIEW THE INVOLVEMENT OF ABERRANT DNA METHYLATION IN VARIOUS TYPES OF INFECTION-ASSOCIATED CANCERS, ALONG WITH INDIVIDUAL INDUCTION MECHANISMS, AND WE DISCUSS THE APPLICATION OF THESE FINDINGS FOR CANCER PREVENTION, DIAGNOSIS, AND THERAPY. 2016 13 6771 37 [ACQUIRED DISORDERS AND EPIGENETICS]. EPIGENETIC MODIFICATIONS, INVOLVING DNA METHYLATION AND HISTONE MODIFICATIONS, ARE MAINTAINED UPON SOMATIC CELL REPLICATION, AND ARE FUNDAMENTAL MECHANISMS FOR CELLULAR MEMORY. DNA METHYLATION OF PROMOTER CPG ISLANDS OF TUMOR-SUPPRESSOR GENES CAN SILENCE THEIR DOWNSTREAM GENES, AND CAN BE CAUSALLY INVOLVED IN CANCER DEVELOPMENT AND PROGRESSION. SINCE THIS EFFECT IS THE SAME WITH THAT OF INACTIVATING MUTATIONS, THE NATURES OF DNA METHYLATION WERE ONCE CONSIDERED TO BE SIMILAR TO MUTATIONS. HOWEVER, RECENTLY, IT WAS REVEALED THAT A LARGE NUMBER OF EPIGENETIC ALTERATIONS ARE PRESENT IN A SINGLE CANCER CELL, THAT A LARGE NUMBER OF CELLS HAVE AN EPIGENETIC ALTERATION OF A SPECIFIC GENE IN NON-CANCEROUS, THUS POLYCLONAL, TISSUES, THAT GENE SPECIFICITY IN METHYLATION INDUCTION IS PRESENT ACCORDING TO TISSUE TYPES AND INDUCERS, AND THAT CHRONIC INFLAMMATION IS DEEPLY INVOLVED IN METHYLATION INDUCTION. THESE FACTS SUGGEST THAT EPIGENETIC ALTERATIONS OF KEY GENES INVOLVED IN ACQUIRED CHRONIC DISORDERS CAN BE PRESENT IN A SIGNIFICANT FRACTION OF CELLS IN A TISSUE, AND THUS CAN IMPAIR THE FUNCTION OF THE TISSUE. ASSOCIATIONS BETWEEN EPIGENETIC ALTERATIONS AND BEHAVIOR, MEMORY, MENTAL DISORDERS, NEUROLOGICAL DISORDERS, METABOLIC DISORDERS, ALLERGY, AUTOIMMUNE DISORDERS, AND OTHER DISORDERS HAVE BEEN REPORTED. FURTHER RESEARCH IN THE FIELD IS NECESSARY TO CLARIFY THE CAUSAL ROLES OF THESE EPIGENETIC ALTERATIONS IN DISEASE DEVELOPMENT, AND TO APPLY THE FINDINGS TO NEW STRATEGIES OF DISEASE PREVENTION, DIAGNOSIS, AND TREATMENT. 2010 14 1562 33 DNA METHYLATION OF ENHANCER ELEMENTS IN MYELOID NEOPLASMS: THINK OUTSIDE THE PROMOTERS? GENE REGULATION THROUGH DNA METHYLATION IS A WELL DESCRIBED PHENOMENON THAT HAS A PROMINENT ROLE IN PHYSIOLOGICAL AND PATHOLOGICAL CELL-STATES. THIS EPIGENETIC MODIFICATION IS USUALLY GROUPED IN REGIONS DENOMINATED CPG ISLANDS, WHICH FREQUENTLY CO-LOCALIZE WITH GENE PROMOTERS, SILENCING THE TRANSCRIPTION OF THOSE GENES. RECENT GENOME-WIDE DNA METHYLATION STUDIES HAVE CHALLENGED THIS PARADIGM, DEMONSTRATING THAT DNA METHYLATION OF REGULATORY REGIONS OUTSIDE PROMOTERS IS ABLE TO INFLUENCE CELL-TYPE SPECIFIC GENE EXPRESSION PROGRAMS UNDER PHYSIOLOGIC OR PATHOLOGIC CONDITIONS. COUPLING GENOME-WIDE DNA METHYLATION ASSAYS WITH HISTONE MARK ANNOTATION HAS ALLOWED FOR THE IDENTIFICATION OF SPECIFIC EPIGENOMIC CHANGES THAT AFFECT ENHANCER REGULATORY REGIONS, REVEALING AN ADDITIONAL LAYER OF COMPLEXITY TO THE EPIGENETIC REGULATION OF GENE EXPRESSION. IN THIS REVIEW, WE SUMMARIZE THE NOVEL EVIDENCE FOR THE MOLECULAR AND BIOLOGICAL REGULATION OF DNA METHYLATION IN ENHANCER REGIONS AND THE DYNAMISM OF THESE CHANGES CONTRIBUTING TO THE FINE-TUNING OF GENE EXPRESSION. WE ALSO ANALYZE THE CONTRIBUTION OF ENHANCER DNA METHYLATION ON THE EXPRESSION OF RELEVANT GENES IN ACUTE MYELOID LEUKEMIA AND CHRONIC MYELOPROLIFERATIVE NEOPLASMS. THE CHARACTERIZATION OF THE ABERRANT ENHANCER DNA METHYLATION PROVIDES NOT ONLY A NOVEL PATHOGENIC MECHANISM FOR DIFFERENT TUMORS BUT ALSO HIGHLIGHTS NOVEL POTENTIAL THERAPEUTIC TARGETS FOR MYELOID DERIVED NEOPLASMS. 2019 15 606 35 BEYOND GENETICS--THE EMERGING ROLE OF EPIGENETIC CHANGES IN HEMATOPOIETIC MALIGNANCIES. THE TERM EPIGENETIC REFERS TO A HERITABLE CHANGE IN GENE EXPRESSION THAT IS MEDIATED BY MECHANISMS OTHER THAN ALTERATIONS IN THE PRIMARY NUCLEOTIDE SEQUENCE. DNA METHYLATION AT CYTOSINE BASES THAT ARE LOCATED 5' TO GUANOSINE WITHIN A CPG DINUCLEOTIDE IS THE MAIN EPIGENETIC MODIFICATION IN HUMANS. PATTERNS OF DNA METHYLATION ARE PROFOUNDLY DERANGED IN HUMAN CANCER AND COMPRISE GENOME-WIDE LOSSES AS WELL AS REGIONAL GAINS IN DNA METHYLATION. HYPERMETHYLATION OF CPG ISLANDS WITHIN GENE PROMOTER REGIONS IS ASSOCIATED WITH TRANSCRIPTIONAL INACTIVATION AND REPRESENTS, IN ADDITION TO GENETIC ABERRATIONS, AN IMPORTANT MECHANISM OF GENE SILENCING IN THE PATHOGENESIS OF HEMATOPOIETIC MALIGNANCIES. THIS EPIGENETIC PHENOMENON ACTS AS AN ALTERNATIVE TO MUTATIONS AND DELETIONS TO DISRUPT TUMOR SUPPRESSOR GENE FUNCTION. A LARGE NUMBER OF GENES INVOLVING FUNDAMENTAL CELLULAR PATHWAYS MAY BE AFFECTED IN VIRTUALLY ALL TYPES OF HUMAN CANCER BY ABERRANT CPG ISLAND METHYLATION IN ASSOCIATION WITH TRANSCRIPTIONAL SILENCING. ALTERED METHYLATION PATTERNS CAN BE USED AS BIOMARKERS FOR CANCER DETECTION, ASSESSMENT OF PROGNOSIS, AND PREDICTION OF RESPONSE TO ANTITUMOR TREATMENT. FURTHERMORE, CLINICAL TRIALS USING EPIGENETICALLY TARGETED THERAPIES HAVE YIELDED PROMISING RESULTS FOR ACUTE AND CHRONIC LEUKEMIAS AS WELL AS FOR MYELODYSPLASTIC SYNDROMES. THE EXPLORATION OF OUR GROWING KNOWLEDGE ABOUT EPIGENETIC ABERRATIONS MAY HELP DEVELOP NOVEL STRATEGIES FOR THE DIAGNOSIS AND TREATMENT OF HEMATOPOIETIC MALIGNANCIES IN THE FUTURE. 2004 16 6790 32 [DNA METHYLATION ANALYSIS IN ENVIRONMENTAL AND OCCUPATIONAL CANCER RESEARCH]. THE PRESENT PAPER REVIEWS RECENT LABORATORY METHODS AND EXPERIMENTAL EVIDENCE CONCERNING EPIGENETIC BIOMARKERS INVOLVED IN CARCINOGENESIS MECHANISMS. WE INTRODUCE DNA METHYLATION AND ITS ROLE IN GENE EXPRESSION CONTROL. DNA METHYLATION ANALYSIS MAY ALLOW TO IDENTIFY EARLY CHANGES LEADING TO CANCER AND OTHER CHRONIC DISEASES. WE DESCRIBE HERE STRATEGIES FOR LABORATORY ANALYSES AND THEIR POSSIBLE APPLICATIONS. WE EXAMINE RESULTS FROM RECENT EXPERIMENTAL STUDIES SUGGESTING THAT THE EFFECTS OF CERTAIN OCCUPATIONAL AGENTS ARE MEDIATED BY ALTERATIONS IN DNA METHYLATION. PLANNING AND CONDUCTING INVESTIGATIONS ON EXPOSED HUMAN SUBJECTS WILL ALLOW TO VERIFY WHETHER DNA METHYLATION CHANGES IDENTIFIED IN ANIMAL AND IN-VITRO STUDIES MAY BE USED AS EARLY-EFFECT AND SUSCEPTIBILITY BIOMARKERS. DNA METHYLATION ANALYSIS HAS THE POTENTIAL FOR FUTURE APPLICATIONS IN RISK ASSESSMENT AND PREVENTION PROGRAMS CONDUCTED ON SUBJECTS EXPOSED TO HUMAN CARCINOGENS. 2005 17 315 32 ALCOHOL, DNA METHYLATION, AND CANCER. CANCER IS ONE OF THE MOST SIGNIFICANT DISEASES ASSOCIATED WITH CHRONIC ALCOHOL CONSUMPTION, AND CHRONIC DRINKING IS A STRONG RISK FACTOR FOR CANCER, PARTICULARLY OF THE UPPER AERODIGESTIVE TRACT, LIVER, COLORECTUM, AND BREAST. SEVERAL FACTORS CONTRIBUTE TO ALCOHOL-INDUCED CANCER DEVELOPMENT (I.E., CARCINOGENESIS), INCLUDING THE ACTIONS OF ACETALDEHYDE, THE FIRST AND PRIMARY METABOLITE OF ETHANOL, AND OXIDATIVE STRESS. HOWEVER, INCREASING EVIDENCE SUGGESTS THAT ABERRANT PATTERNS OF DNA METHYLATION, AN IMPORTANT EPIGENETIC MECHANISM OF TRANSCRIPTIONAL CONTROL, ALSO COULD BE PART OF THE PATHOGENETIC MECHANISMS THAT LEAD TO ALCOHOL-INDUCED CANCER DEVELOPMENT. THE EFFECTS OF ALCOHOL ON GLOBAL AND LOCAL DNA METHYLATION PATTERNS LIKELY ARE MEDIATED BY ITS ABILITY TO INTERFERE WITH THE AVAILABILITY OF THE PRINCIPAL BIOLOGICAL METHYL DONOR, S-ADENOSYLMETHIONINE (SAME), AS WELL AS PATHWAYS RELATED TO IT. SEVERAL MECHANISMS MAY MEDIATE THE EFFECTS OF ALCOHOL ON DNA METHYLATION, INCLUDING REDUCED FOLATE LEVELS AND INHIBITION OF KEY ENZYMES IN ONE-CARBON METABOLISM THAT ULTIMATELY LEAD TO LOWER SAME LEVELS, AS WELL AS INHIBITION OF ACTIVITY AND EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION (I.E., DNA METHYLTRANSFERASES). FINALLY, VARIATIONS (I.E., POLYMORPHISMS) OF SEVERAL GENES INVOLVED IN ONE-CARBON METABOLISM ALSO MODULATE THE RISK OF ALCOHOL-ASSOCIATED CARCINOGENESIS. 2013 18 6616 35 UNCOVERING THE DNA METHYLOME IN CHRONIC LYMPHOCYTIC LEUKEMIA. OVER THE PAST TWO DECADES, ABERRANT DNA METHYLATION HAS EMERGED AS A KEY PLAYER IN THE PATHOGENESIS OF CHRONIC LYMPHOCYTIC LEUKEMIA (CLL), AND KNOWLEDGE REGARDING ITS BIOLOGICAL AND CLINICAL CONSEQUENCES IN THIS DISEASE HAS EVOLVED RAPIDLY. SINCE THE INITIAL STUDIES RELATING DNA HYPOMETHYLATION TO GENOMIC INSTABILITY IN CLL, A PLETHORA OF REPORTS HAVE FOLLOWED SHOWING THE IMPACT OF DNA HYPERMETHYLATION IN SILENCING VITAL SINGLE GENE PROMOTERS AND THE REVERSIBLE NATURE OF DNA METHYLATION THROUGH INHIBITOR DRUGS. WITH THE RECOGNITION THAT DNA HYPERMETHYLATION EVENTS COULD POTENTIALLY ACT AS NOVEL PROGNOSTIC AND TREATMENT TARGETS IN CLL, THE SEARCH FOR ABERRANTLY METHYLATED GENES, GENE FAMILIES AND PATHWAYS HAS ENSUED. SUBSEQUENTLY, THE ADVENT OF MICROARRAY AND NEXT-GENERATION SEQUENCING TECHNOLOGIES HAS SUPPORTED THE HUNT FOR SUCH TARGETS, ALLOWING EXPLORATION OF THE METHYLATION LANDSCAPE IN CLL AT AN UNPRECEDENTED SCALE. IN LIGHT OF THESE ANALYSES, WE NOW UNDERSTAND THAT DIFFERENT CLL PROGNOSTIC SUBGROUPS ARE CHARACTERIZED BY DIFFERENTIAL METHYLATION PROFILES; WE RECOGNIZE DNA METHYLATION OF A NUMBER OF SIGNALING PATHWAYS GENES TO BE ALTERED IN CLL, AND ACKNOWLEDGE THE ROLE OF DNA METHYLATION OUTSIDE OF TRADITIONAL CPG ISLAND PROMOTERS AS FUNDAMENTAL PLAYERS IN THE REGULATION OF GENE EXPRESSION. TODAY, THE SIGNIFICANCE AND TIMING OF ALTERED DNA METHYLATION WITHIN THE COMPLEX EPIGENETIC NETWORK OF CONCOMITANT EPIGENETIC MESSENGERS SUCH AS HISTONES AND MIRNAS IS AN INTENSIVE AREA OF RESEARCH. IN CLL, IT APPEARS THAT DNA METHYLATION IS A RATHER STABLE EPIGENETIC MARK OCCURRING RATHER EARLY IN THE DISEASE PATHOGENESIS. HOWEVER, OTHER CONSEQUENCES, SUCH AS HOW AND WHY ABERRANT METHYLATION MARKS OCCUR, ARE LESS EXPLORED. IN THIS REVIEW, WE WILL NOT ONLY PROVIDE A COMPREHENSIVE SUMMARY OF THE CURRENT LITERATURE WITHIN THE EPIGENETICS FIELD OF CLL, BUT ALSO HIGHLIGHT SOME OF THE NOVEL FINDINGS RELATING TO WHEN, WHERE, WHY AND HOW ALTERED DNA METHYLATION MATERIALIZES IN CLL. 2013 19 3686 28 INFLAMMATION-RELATED ABERRANT PATTERNS OF DNA METHYLATION: DETECTION AND ROLE IN EPIGENETIC DEREGULATION OF CANCER CELL TRANSCRIPTOME. IT IS NOW APPARENT THAT EPIGENETIC ABNORMALITIES, IN PARTICULAR ALTERED DNA METHYLATION, PLAY A CRUCIAL ROLE IN THE DEVELOPMENT AND PROGRESSION OF HUMAN CANCERS. DNA HYPERMETHYLATION AT PROMOTER CPG ISLANDS IS NOW RECOGNIZED AS A THIRD MECHANISM BY WHICH INACTIVATION OF TUMOR SUPPRESSOR GENES OCCURS. ABERRANT CPG ISLAND HYPERMETHYLATION IS ALSO FREQUENTLY OBSERVED IN CHRONIC INFLAMMATION AND PRECANCEROUS LESIONS, WHICH SUGGESTS THAT IT IS AN EARLY EVENT IN TUMORIGENESIS THAT COULD SERVE AS A USEFUL TUMOR MARKER. A VARIETY OF SCREENING TECHNIQUES HAVE BEEN DEVELOPED FOR GENOME-WIDE SCREENING OF METHYLATION STATUS. OF THOSE, TRANSCRIPTOME ANALYSIS COUPLED WITH PHARMACOLOGICAL UNMASKING HAS EMERGED AS A POWERFUL TOOL FOR REVEALING DNA METHYLATION PATTERNS IN CANCER CELLS AND IDENTIFYING NEW TUMOR MARKER CANDIDATES. 2009 20 1518 31 DNA METHYLATION AS AN EPIGENETIC MECHANISM IN THE DEVELOPMENT OF MULTIPLE SCLEROSIS. THE EPIGENETIC MECHANISMS OF GENE EXPRESSION REGULATION ARE A GROUP OF THE KEY CELLULAR AND MOLECULAR PATHWAYS THAT LEAD TO INHERITED ALTERATIONS IN GENES' ACTIVITY WITHOUT CHANGING THEIR CODING SEQUENCE. DNA METHYLATION AT THE C5 POSITION OF CYTOSINE IN CPG DINUCLEOTIDES IS AMONGST THE CENTRAL EPIGENETIC MECHANISMS. CURRENTLY, THE NUMBER OF STUDIES THAT ARE DEVOTED TO THE IDENTIFICATION OF METHYLATION PATTERNS SPECIFIC TO MULTIPLE SCLEROSIS (MS), A SEVERE CHRONIC AUTOIMMUNE DISEASE OF THE CENTRAL NERVOUS SYSTEM, IS ON A RAPID RISE. HOWEVER, THE ISSUE OF THE CONTRIBUTION OF DNA METHYLATION TO THE DEVELOPMENT OF THE DIFFERENT CLINICAL PHENOTYPES OF THIS HIGHLY HETEROGENEOUS DISEASE HAS ONLY BEGUN TO ATTRACT THE ATTENTION OF RESEARCHERS. THIS REVIEW SUMMARIZES THE DATA ON THE MOLECULAR MECHANISMS UNDERLYING DNA METHYLATION AND THE MS RISK FACTORS THAT CAN AFFECT THE DNA METHYLATION PROFILE AND, THEREBY, MODULATE THE EXPRESSION OF THE GENES INVOLVED IN THE DISEASE'S PATHOGENESIS. THE FOCUS OF OUR ATTENTION IS CENTERED ON THE ANALYSIS OF THE PUBLISHED DATA ON THE DIFFERENTIAL METHYLATION OF DNA FROM VARIOUS BIOLOGICAL SAMPLES OF MS PATIENTS OBTAINED USING BOTH THE CANDIDATE GENE APPROACH AND HIGH-THROUGHPUT METHODS. 2021